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PEARSON
SPECIALISTMATHEMATICSQUEENSLANDEXAM PREPARATION WORKBOOK
UNITS 3 & 4
Sample
page
s
iii
About this Pearson Specialist Mathematics 12 Exam Preparation Workbook
Amy HawkeMathematics teacher, QLDAuthor
Antje Leigh-LancasterLead publisherPortfolio Manager for K12 MathematicsPearson Australia
Lindy BaylesMathematics teacher, VICDevelopment editor
Thomas SchmiererMathematics teacher, QLDAnswer checker
Daniel Hernandez NavasPublisherContent and learning specialistPearson Australia
PEARSON
SPECIALIST MATHEMATICSQUEENSLANDEXAM PREPARATION WORKBOOK
UNITS 3 & 4
PEARSON
SPECIALIST MATHEMATICSQUEENSLANDEXAM PREPARATION WORKBOOK
UNITS 3 & 4
The purpose of the Pearson Exam Preparation Workbook is to assist students in their preparation for the QCAA external exams. Answering previous external exam questions is an effective way to do this, as it offers well-constructed questions at the appropriate level.
This Pearson Exam Preparation Workbook includes previous external exam questions from New South Wales, South Australia and Victoria. Given that both the syllabuses and the access to allowed technologies varies across the states, the author has reviewed questions from years 2000 to 2017 to select those questions that align with the QCAA syllabus.
These questions were then categorised using the QCAA three levels of difficulty: simple familiar, complex familiar and complex unfamiliar. This matches the QCAA external exam structure, which indicates that in Paper 1 and Paper 2, marks will be allocated in the following approximate proportions:
• 60% simple familiar
• 20% complex familiar
• 20% complex unfamiliar.
The source of each question in the Pearson Exam Preparation Workbook is referenced at the start of the question. At times, there may be some variation between the notation used in the questions and that used by the QCAA; the authors have made note of this within the worked solution as applicable.
Each worked solution has indicative mark allocations. As official marking schemes are not released by state examining bodies, the mark allocations in the Pearson Exam Preparation Workbook are based on the author’s and reviewer’s on-balance judgement and their teaching experience.
Writing and development teamWe are grateful to the following people for their time and expertise in contributing to Pearson Specialist Mathematics 12 Exam Preparation Workbook.
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Step 1: Key areas of knowledge The purpose of making these notes is to first identify what is required to be done, and how it might be done, without doing it at this stage.
For each question, note the topic(s) of mathematics it draws on, formulas you think will be needed, and any other comments you feel will help you work out the answer.
Then move on to the next question in that set.
How to use this workbook
Pearson Specialist Mathematics 12 Queensland Exam Preparation Workbook, Units 3 & 4This exam preparation workbook has been developed to assist students in their preparation for the QCAA external exams. It provides previous external exam questions from New South Wales, South Australia and Victoria that align with the QCAA syllabus. All questions are categorised into the QCAA three levels of difficulty—simple familiar, complex familiar and complex unfamiliar—to match the QCAA external exam structure.
The questions have been grouped into convenient sets, with the intention that each question set is tackled in one sitting.
Levels of difficultyLevels of difficulty are indicated using a three-striped label.
Simple familiar: Complex familiar:
Complex unfamiliar:
These are used in two ways:
1 To show the level of difficulty for the whole question set
2 To show the level of difficulty of individual question parts when they differ from that of the question set level. In such cases, all parts of that question are labelled.
Technology free questionsQuestions to be completed without the use of any technology will have a crossed out calculator image beside them:
162 Pearson Specialist Mathematics 12 Exam Preparation Workbook Queensland ISBN 978 1 4886 2147 5
Key areas of knowledge
Set 18 Complex unfamiliar exam questions1 12 marks, 18 minutes
[Question 5 from Section 2 VCE Specialist Mathematics Exam 2, 2013, illustration redrawn]A waterskier moves from side to side behind a speedboat that is travelling in a straight line along a still lake.The position vector of the waterskier relative to a fixed observation point on the shore of the lake is given by
7.5 50 10 sin6
r i jπ( ) = + −
t t t
t seconds after passing a marker buoy.The components of the position vector are measured in metres, where i is a unit vector in the direction of motion of the speedboat, and j is a unit vector perpendicular to i to the left of the direction of motion of the speedboat. The diagram below represents the view from above.
Path of waterskier
Waterskier
SpeedboatTow ropePath of speedboat
ji
(a) Find ( )tr and hence determine the minimum and maximum speeds of the waterskier. Give your answers in metres per second, correct to one decimal place.
(b) Find the times when the acceleration of the waterskier is zero.
3 marks (4.5 mins)
2 marks (3 mins)
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154 Pearson Specialist Mathematics 12 Exam Preparation Workbook Queensland ISBN 978 1 4886 2147 5
Key areas of knowledge
Set 17 Complex unfamiliar exam questions1 4 marks, 6 minutes
[Question 10 from VCE Specialist Mathematics Exam 1, 2010, illustration redrawn]Part of the graph with equation ( )= − +1 12y x x is shown below.
x
y
1.5 20 0.5-0.5-1-1.5-2 1
2
1
-1
-2
Find the area that is bounded by the curve and the x-axis. Give your answer in the form a b
c where a, b and c are integers.
My mark:
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Get yourself exam ready using this 5-step preparation sequence
163
ISBN 978 1 4886 2147 5 Complex unfamiliar exam questions Set 18
Key areas of knowledge Later, the waterskier performs a jump from the top of a 10 m long ramp, which is inclined at 30° to the horizontal. To do this, the speedboat travels beside the ramp and keeps the waterskier’s speed at 15 m/s directly up the ramp, until the waterskier reaches the top. Then the speedboat slows, so that the tow rope slackens and remains slack after the waterskier leaves the top of the ramp. Assume negligible air resistance on the waterskier, who is then subject only to the force of gravity.
30°
10 m
(c) Find the time it takes for the waterskier to hit the water after leaving the top of the ramp. Give your answer in seconds, correct to the nearest one hundredth of a second.
(d) After leaving the top of the ramp, how far in the horizontal direction does the waterskier travel before hitting the water? Give your answer in metres, correct to the nearest metre.
2 marks (3 mins)
1 mark (1.5 mins)
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ISBN 978 1 4886 2147 5 Complex unfamiliar exam questions Set 18
Key areas of knowledge Later, the waterskier performs a jump from the top of a 10 m long ramp, which is inclined at 30° to the horizontal. To do this, the speedboat travels beside the ramp and keeps the waterskier’s speed at 15 m/s directly up the ramp, until the waterskier reaches the top. Then the speedboat slows, so that the tow rope slackens and remains slack after the waterskier leaves the top of the ramp. Assume negligible air resistance on the waterskier, who is then subject only to the force of gravity.
30°
10 m
(c) Find the time it takes for the waterskier to hit the water after leaving the top of the ramp. Give your answer in seconds, correct to the nearest one hundredth of a second.
(d) After leaving the top of the ramp, how far in the horizontal direction does the waterskier travel before hitting the water? Give your answer in metres, correct to the nearest metre.
2 marks (3 mins)
1 mark (1.5 mins)
162 Pearson Specialist Mathematics 12 Exam Preparation Workbook Queensland ISBN 978 1 4886 2147 5
Key areas of knowledge
Set 18 Complex unfamiliar exam questions1 12 marks, 18 minutes
[Question 5 from Section 2 VCE Specialist Mathematics Exam 2, 2013, illustration redrawn]A waterskier moves from side to side behind a speedboat that is travelling in a straight line along a still lake.The position vector of the waterskier relative to a fixed observation point on the shore of the lake is given by
7.5 50 10 sin6
r i jπ( ) = + −
t t t
t seconds after passing a marker buoy.The components of the position vector are measured in metres, where i is a unit vector in the direction of motion of the speedboat, and j is a unit vector perpendicular to i to the left of the direction of motion of the speedboat. The diagram below represents the view from above.
Path of waterskier
Waterskier
SpeedboatTow ropePath of speedboat
ji
(a) Find ( )tr and hence determine the minimum and maximum speeds of the waterskier. Give your answers in metres per second, correct to one decimal place.
(b) Find the times when the acceleration of the waterskier is zero.
3 marks (4.5 mins)
2 marks (3 mins)
Sample
page
s
Step 2: Complete questions Complete all the questions within the question set using the space provided.
Question sets have been structured according to level of difficulty, with each question set covering a range of topics from the syllabus.
Step 4: Examination report and reflection Review the marks obtained from past students, read the information in the Examination report section (where available) and reflect on your own solution.
Use the Notes and pointers section to write down any relevant key reminders to yourself about common errors, key rules etc.
Step 5: Self-reflection: Question set notes and pointers summaryReflect on all the questions within one set, review your comments in the individual Notes and pointers sections, and use these to complete a summary of the overall question set.
Use the Red, Amber and Green categories to note what you need to revise or don’t understand, what you need to watch out for, and what you did well.
Once all sets are completed, these summaries will help in giving you direction on where to focus your further revision.
Step 3: Check your answerReview and mark your answers according to the solutions provided in the corresponding worked solutions.
1
ISBN 978 1 4886 2147 5 Self-reflection: Question set notes and pointers summary
Self-reflection: Question set Notes and pointers summary
Red
Ideas, concepts, rules, topics I need to revise or don’t understand
Amber
Common errors I tend to make and need to watch out for
Green
Things I always do well
Set 1
Set 2
Set 3
Set 4
Set 5
Set 6
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12 Pearson Specialist Mathematics 12 Exam Preparation Workbook Queensland ISBN 978 1 4886 2147 5
Key areas of knowledge
Set 2 Simple familiar exam questions1 6 marks, 9 minutes
[Question 1 from Section 2, VCE Specialist Mathematics Exam 2, 2011, illustration redrawn]Consider the graph with the rule 1z i− = where ∈z .(a) Write this rule in cartesian form.
(b) Find the points of intersection of the graphs with the rules 1z i− = and 1 1z − = in cartesian form.
(c) Sketch and label the graphs with rules 1z i− = and 1 1z − = on the argand diagram below.
3210-3 -2 -1
3
2
1
-3
-2
-1
Re(z)
Im(z)
2 marks (3 mins)
2 marks (3 mins)
2 marks (3 mins)
My total marks:
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16 Pearson Specialist Mathematics 12 Exam Preparation Workbook Queensland ISBN 978 1 4886 2147 5
Examination report comments Worked solutionsMarks
Set 2Marks 0 1 2 Average% 14 10 76 1.6
+ − =x iy i 1 ⇒ ( )+ − =x y 1 12 2
This question was generally quite well done. However, a common error was that students tried to make y the subject and neglect the ± sign. Another common error was getting i mixed up in the answer.
1 mark for correctly translating centre1 mark for correctly translating the radius
Notes and pointers
1 (a) In complex form the circle is represented by 1z z r− = . The coordinates of the centre and
the length of the radius can be determined and substituted into the cartesian form of the circle. An alternative method is to substitute z x yi= + into the given equation, evaluate the modulus, and simplify algebraically.
|z − z1| = rz1 = i, r = 1
∴ centre (1,0), radius is 1 (x − 1)2 + y2 = 1
Marks 0 1 2 Average% 21 9 70 1.5
This question was generally done well. Equivalent forms of points (0,0) and (1,1) were also accepted.
1 mark for correctly identifying (0, 0)1 mark for correctly identifying (1, 1)
Notes and pointers
(b) There are two common approaches to solving this question. First, both equations can be sketched or drawn on a graphics calculator, and the coordinates of the point of intersection can be determined. Second, an algebraic solution can be found. This is shown below. If an algebraic solution is used, graphing on a graphics calculator is an appropriate method to check that results are reasonable.
1 1z − = ⇒ 1 12 2x y( )+ − = Equate both circles:
1 12 1 2 1
-2 -2
2 2 2 2
2 2 2 2
x y x yx x y x y y
x yx y
( )( )− + = + −− + + = + − +
==
Substitute y = x into the equation of the first circle and solve for x:
1 12 1 1
2 2 02 02 1 0
2 2
2 2
2
2
x xx x x
x xx x
x x( )
( )
( )
− + =− + + =
− =− =− =
∴ x = 0 and x = 1 Given x = y the points of intersection are (0,0) and (1,1).
1
1
2
Simple familiar worked solutions and examination report
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16 Pearson Specialist Mathematics 12 Exam Preparation Workbook Queensland ISBN 978 1 4886 2147 5
Examination report comments Worked solutionsMarks
Set 2Marks 0 1 2 Average% 14 10 76 1.6
+ − =x iy i 1 ⇒ ( )+ − =x y 1 12 2
This question was generally quite well done. However, a common error was that students tried to make y the subject and neglect the ± sign. Another common error was getting i mixed up in the answer.
1 mark for correctly translating centre1 mark for correctly translating the radius
Notes and pointers
1 (a) In complex form the circle is represented by 1z z r− = . The coordinates of the centre and
the length of the radius can be determined and substituted into the cartesian form of the circle. An alternative method is to substitute z x yi= + into the given equation, evaluate the modulus, and simplify algebraically.
|z − z1| = rz1 = i, r = 1
∴ centre (1,0), radius is 1 (x − 1)2 + y2 = 1
Marks 0 1 2 Average% 21 9 70 1.5
This question was generally done well. Equivalent forms of points (0,0) and (1,1) were also accepted.
1 mark for correctly identifying (0, 0)1 mark for correctly identifying (1, 1)
Notes and pointers
(b) There are two common approaches to solving this question. First, both equations can be sketched or drawn on a graphics calculator, and the coordinates of the point of intersection can be determined. Second, an algebraic solution can be found. This is shown below. If an algebraic solution is used, graphing on a graphics calculator is an appropriate method to check that results are reasonable.
1 1z − = ⇒ 1 12 2x y( )+ − = Equate both circles:
1 12 1 2 1
-2 -2
2 2 2 2
2 2 2 2
x y x yx x y x y y
x yx y
( )( )− + = + −− + + = + − +
==
Substitute y = x into the equation of the first circle and solve for x:
1 12 1 1
2 2 02 02 1 0
2 2
2 2
2
2
x xx x x
x xx x
x x( )
( )
( )
− + =− + + =
− =− =− =
∴ x = 0 and x = 1 Given x = y the points of intersection are (0,0) and (1,1).
1
1
2
Simple familiar worked solutions and examination report
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v
12 Pearson Specialist Mathematics 12 Exam Preparation Workbook Queensland ISBN 978 1 4886 2147 5
Key areas of knowledge
Set 2 Simple familiar exam questions1 6 marks, 9 minutes
[Question 1 from Section 2, VCE Specialist Mathematics Exam 2, 2011, illustration redrawn]Consider the graph with the rule 1z i− = where ∈z .(a) Write this rule in cartesian form.
(b) Find the points of intersection of the graphs with the rules 1z i− = and 1 1z − = in cartesian form.
(c) Sketch and label the graphs with rules 1z i− = and 1 1z − = on the argand diagram below.
3210-3 -2 -1
3
2
1
-3
-2
-1
Re(z)
Im(z)
2 marks (3 mins)
2 marks (3 mins)
2 marks (3 mins)
My total marks:
12 Pearson Specialist Mathematics 12 Exam Preparation Workbook Queensland ISBN 978 1 4886 2147 5
Key areas of knowledge
Set 2 Simple familiar exam questions1 6 marks, 9 minutes
[Question 1 from Section 2, VCE Specialist Mathematics Exam 2, 2011, illustration redrawn]Consider the graph with the rule 1z i− = where ∈z .(a) Write this rule in cartesian form.
(b) Find the points of intersection of the graphs with the rules 1z i− = and 1 1z − = in cartesian form.
(c) Sketch and label the graphs with rules 1z i− = and 1 1z − = on the argand diagram below.
3210-3 -2 -1
3
2
1
-3
-2
-1
Re(z)
Im(z)
2 marks (3 mins)
2 marks (3 mins)
2 marks (3 mins)
My total marks:
16 Pearson Specialist Mathematics 12 Exam Preparation Workbook Queensland ISBN 978 1 4886 2147 5
Examination report comments Worked solutionsMarks
Set 2Marks 0 1 2 Average% 14 10 76 1.6
+ − =x iy i 1 ⇒ ( )+ − =x y 1 12 2
This question was generally quite well done. However, a common error was that students tried to make y the subject and neglect the ± sign. Another common error was getting i mixed up in the answer.
1 mark for correctly translating centre1 mark for correctly translating the radius
Notes and pointers
1 (a) In complex form the circle is represented by 1z z r− = . The coordinates of the centre and
the length of the radius can be determined and substituted into the cartesian form of the circle. An alternative method is to substitute z x yi= + into the given equation, evaluate the modulus, and simplify algebraically.
|z − z1| = rz1 = i, r = 1
∴ centre (1,0), radius is 1 (x − 1)2 + y2 = 1
Marks 0 1 2 Average% 21 9 70 1.5
This question was generally done well. Equivalent forms of points (0,0) and (1,1) were also accepted.
1 mark for correctly identifying (0, 0)1 mark for correctly identifying (1, 1)
Notes and pointers
(b) There are two common approaches to solving this question. First, both equations can be sketched or drawn on a graphics calculator, and the coordinates of the point of intersection can be determined. Second, an algebraic solution can be found. This is shown below. If an algebraic solution is used, graphing on a graphics calculator is an appropriate method to check that results are reasonable.
1 1z − = ⇒ 1 12 2x y( )+ − = Equate both circles:
1 12 1 2 1
-2 -2
2 2 2 2
2 2 2 2
x y x yx x y x y y
x yx y
( )( )− + = + −− + + = + − +
==
Substitute y = x into the equation of the first circle and solve for x:
1 12 1 1
2 2 02 02 1 0
2 2
2 2
2
2
x xx x x
x xx x
x x( )
( )
( )
− + =− + + =
− =− =− =
∴ x = 0 and x = 1 Given x = y the points of intersection are (0,0) and (1,1).
1
1
2
Simple familiar worked solutions and examination report
Sample
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vi
About this Exam Preparation Workbook iii
Writing and development team iii
How to use this workbook iv
Self-reflection: Question set notes and pointers summary
Summary of sets 1–6 1
Summary of sets 7–11 2
Summary of sets 12–16 3
Summary of sets 17–21 4
Simple familiar question sets
Question Set 1 5
Worked solutions Set 1 8
Question Set 2 12
Worked solutions Set 2 16
Question Set 3 22
Worked solutions Set 3 26
Question Set 4 30
Worked solutions Set 4 35
Question Set 5 40
Worked solutions Set 5 44
Question Set 6 49
Worked solutions Set 6 54
Question Set 7 59
Worked solutions Set 7 63
Contents
Complex familiar question sets
Question Set 8 67
Worked solutions Set 8 72
Question Set 9 80
Worked solutions Set 9 84
Question Set 10 90
Worked solutions Set 10 94
Question Set 11 99
Worked solutions Set 11 102
Question Set 12 107
Worked solutions Set 12 112
Question Set 13 119
Worked solutions Set 13 122
Question Set 14 128
Worked solutions Set 14 132
Complex unfamiliar question sets
Question Set 15 136
Worked solutions Set 15 141
Question Set 16 148
Worked solutions Set 16 151
Question Set 17 154
Worked solutions Set 17 158
Question Set 18 162
Worked solutions Set 18 167
Question Set 19 172
Worked solutions Set 19 175
Question Set 20 179
Worked solutions Set 20 182
Question Set 21 185
Worked solutions Set 21 188
Sample
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12 Pearson Specialist Mathematics 12 Exam Preparation Workbook Queensland ISBN 978 1 4886 2147 5
Key areas of knowledge
Set 2 Simple familiar exam questions
1 6 marks, 9 minutes [Question 1 from Section 2, VCE Specialist Mathematics Exam 2, 2011, illustration redrawn]
Consider the graph with the rule 1z i− = where ∈z .(a) Write this rule in cartesian form.
(b) Find the points of intersection of the graphs with the rules
1z i− = and 1 1z − = in cartesian form.
(c) Sketch and label the graphs with rules 1z i− = and 1 1z − = on
the argand diagram below.
3210-3 -2 -1
3
2
1
-3
-2
-1
Re(z)
Im(z)
2 marks (3 mins)
2 marks (3 mins)
2 marks (3 mins)
My total marks:
Sample
page
s
13ISBN 978 1 4886 2147 5 Simple familiar exam questions Set 2
Key areas of knowledge 2 4 marks, 6 minutes [Question 9 VCE Specialist Mathematics Exam 1, 2015]
Consider the curve represented by 32
92 2x xy y− + = .(a) Find the gradient of the curve at any point ,x y( ).
(b) Find the equation of the tangent to the curve at the point (3,0) and
find the equation of the tangent to the curve at the point 0, 6( ). Write each equation in the form y ax b= + .
3 3 marks, 4.5 minutes [Question 13c from Section 2, HSC Mathematics Extension 1, 2015]
Prove by mathematical induction that for all integers 1n ≥ , 12!
23!
34!
...1 !
1 11 !
nn n( ) ( )+ + + +
+= −
+
2 marks (3 mins)
2 marks (3 mins)
My total marks:
My mark:
Sample
page
s
14 Pearson Specialist Mathematics 12 Exam Preparation Workbook Queensland ISBN 978 1 4886 2147 5
Key areas of knowledge 4 1 mark, 1.5 minutes [Question 17 from Section 1, VCE Specialist Mathematics Exam 2, 2014]
The acceleration vector of a particle that starts from rest is given by ( ) -4 sin(2 ) 20cos(2 ) 20 -2a t t i t j e kt
= + − , where 0t ≥ .The velocity of the particle, v t
( ), is given by A ( ) ( )− +
-8cos 2 40sin 2 40 -2t i t j e kt B 2cos 2 10 sin 2 10 -2t i t j e kt
( ) ( )+ + C 8 8cos 2 40 sin 2 40 40-2t i t j e kt
( )( )( ) ( )− − + − D 2cos 2 2 10 sin 2 10 10-2t i t j e kt
( )( )( ) ( )− + + − E 4 cos 2 4 20 sin 2 20 20 -2t i t j e kt
( )( )( ) ( )− + + −
5 1 mark, 1.5 minutes [Question 20 from Section A, VCE Specialist Mathematics Exam 2, 2016]
The lifetime of a certain brand of batteries is normally distributed with a mean lifetime of 20 hours and a standard deviation of two hours. A random sample of 25 batteries is selected.The probability that the mean lifetime of this sample of 25 batteries exceeds 19.3 hours isA 0.0401 B 0.1368 C 0.6103 D 0.8632 E 0.9599
6 5 marks, 7.5 minutes [Question 2(a) only from Section 2, VCE Specialist Mathematics Exam 2, 2014]
Consider the complex number 3 31z i= − .(a) (i) Express 1z in polar form.
(ii) Find ( )Arg 1
4z .
My mark:
My mark:
2 marks (3 mins)
1 mark (1.5 mins)
Sample
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15ISBN 978 1 4886 2147 5 Simple familiar exam questions Set 2
Key areas of knowledge (iii) Given that 3 31z i= − is one root of the equation 24 3 03z + = , find the other two roots, expressing your answers in cartesian form.
7 1 mark, 1.5 minutes [Question 10 from Section A, VCE Specialist Mathematics Exam 2, 2016, illustration redrawn]
40-1-2-3-4 1 2 3
3
1
2
-1
-2
-3
y
x
The direction field for the differential equation 0dydx
x y+ + = is
shown above. A solution to this differential equation that includes 0,-1( ) could also include
A 3,-1( ) B 3.5,-2.5( ) C -1.5,-2( ) D 2.5,-1( ) E 2.5,1( )
8 1 mark, 1.5 minutes [Question 5 from Section 1, VCE Northern Hemisphere Specialist Mathematics Exam 2, 2017]
Given that A, B, C and D are non-zero rational numbers, the
expression 3 12 2
xx x( )
+−
can be represented in partial fraction form as
A 2
Ax
Bx( )+
− B
2 2Ax
Bx( )
+−
C 2 2 2
Ax
Bx
Cx( ) ( )
+−
+−
D 22
Ax
Bx
Cx( )+ +
−
E 2 2 2
Ax
Bx
Cx Dx( ) ( )
+−
+ +−
2 marks (3 mins)
My total marks:
My mark:
My mark:
Sample
page
s
16 Pearson Specialist Mathematics 12 Exam Preparation Workbook Queensland ISBN 978 1 4886 2147 5
Examination report comments Worked solutions Marks
Set 2Marks 0 1 2 Average
% 14 10 76 1.6
+ − =x iy i 1 ⇒ ( )+ − =x y 1 12 2
This question was generally quite well done.
However, a common error was that students tried to
make y the subject and neglect the ± sign. Another
common error was getting i mixed up in the answer.
1 mark for correctly translating centre
1 mark for correctly translating the radius
Notes and pointers
1 (a) In complex form the circle is represented by 1z z r− = . The coordinates of the centre and
the length of the radius can be determined and substituted into the cartesian form of the circle. An alternative method is to substitute z x yi= + into the given equation, evaluate the modulus, and simplify algebraically.
|z − z1| = rz1 = i, r = 1
∴ centre (1,0), radius is 1
(x − 1)2 + y2 = 1
Marks 0 1 2 Average
% 21 9 70 1.5
This question was generally done well. Equivalent
forms of points (0,0) and (1,1) were also accepted.
1 mark for correctly identifying (0, 0)
1 mark for correctly identifying (1, 1)
Notes and pointers
(b) There are two common approaches to solving this question. First, both equations can be sketched or drawn on a graphics calculator, and the coordinates of the point of intersection can be determined. Second, an algebraic solution can be found. This is shown below. If an algebraic solution is used, graphing on a graphics calculator is an appropriate method to check that results are reasonable.
1 1z − = ⇒ 1 12 2x y( )+ − =
Equate both circles:
1 12 1 2 1
-2 -2
2 2 2 2
2 2 2 2
x y x yx x y x y y
x yx y
( )( )− + = + −− + + = + − +
==
Substitute y = x into the equation of the first circle and solve for x:
1 12 1 1
2 2 0
2 0
2 1 0
2 2
2 2
2
2
x xx x x
x x
x x
x x( )
( )
( )
− + =− + + =
− =
− =
− =
∴ x = 0 and x = 1
Given x = y the points of intersection are (0,0) and (1,1).
1
1
2
Simple familiar worked solutions and examination report
Sample
page
s
17ISBN 978 1 4886 2147 5 Simple familiar worked solutions and examination report Set 2
Examination report comments Worked solutions Marks
Marks 0 1 2 Average
% 22 16 62 1.4
This question was reasonably well done. Common
errors included the incomplete labelling of the circles,
and circles having wrong centres. A small number of
students gave lines or points instead of circles.
1 mark for correctly sketching z i 1− =
1 mark for correctly sketching z 1 1− =
Notes and pointers
(c)
Marks 0 1 2 Average
% 14 16 70 1.6
This question was answered well. Most students
correctly used the product and chain rules. A
number of sign errors appeared on the left-hand
scale, while some left the right-hand side as 9
after differentiating the left-hand scale. Algebraic
simplification errors were common.
1 mark for correctly identifying and using chain and product rules in implicit differentiation
1 mark for the correct answer
Notes and pointers
2 (a) It is important to identify where the chain and product rules will apply, and also to note the subtraction sign in front of the second term on the left-hand side.
( )( )
− +
=
− +
=
− +
+ =
− − + =
− − + =
−
= +
=−−
32
(9)
( )32
0
2 ( ) ( )32
0
2 ( )32
2 0
232
2 0
62
-2
23
2 2
2 2
2
ddx
x xy yd
dxd
dxx
ddx
xyd
dxy
x xd
dxy y
ddx
xddy
ydydx
x xddy
ydydx
y ydydx
x xdydx
y ydydx
dydx
y x x y
dydx
y xy x
The gradient of the curve at any point (x, y) is 2
3dydx
y xy x
=−−
.
20-1-2 1
2|z – i| = 1
|z – 1| = 11
-1
-2
Im(z)
Re(z)
2
1
1
Sample
page
s
18 Pearson Specialist Mathematics 12 Exam Preparation Workbook Queensland ISBN 978 1 4886 2147 5
Examination report comments Worked solutions Marks
Marks 0 1 2 Average
% 18 20 62 1.5
This question was well answered. The most common
errors were only finding one equation and arithmetic
errors in converting one or both equations to the
required form.
1 mark for finding the first equation to the tangent correctly
1 mark for finding the second equation to the tangent correctly
Notes and pointers
(b) Use the previous answer to determine the gradient of the tangent to the curve at each point.
For point (3, 0)0 2 33 0 32
m =− ×× −
=
0 2 32 6
1 1y y m x xy x
y x
( )( )
− = −− = −
= −
The equation of the tangent to the curve at the point (3, 0) is 2 6y x= − .
For point 0, 6( ),=
− ×−
=
6 2 03 6 0
13
m
( )( )
− = −
− = −
= +
613
0
13
6
1 1y y m x x
y x
y x
The equation of the tangent to the curve at the point
0, 6( ) is 3
6yx
= +
Note: This question is from a NSW HSC examination
paper. Examiner reports do not supply a breakdown of
marks achieved by the student cohort for these papers.
1 mark for verifying the initial case
1 mark for verifying the initial case and using inductive assumption
1 mark for a complete and correct proof
Notes and pointers
3 The assumption n = k must be used when proving for n = k + 1.
When n = 1,
RHS 11
1 1 !
112!
12
LHS
( )= −+
= − = =
The statement is therefore true for n = 1.
Assume the result is true for n = k
i.e. assume 12!
23!
34!
...1 !
11
1 !k
k k( ) ( )+ + + ++
= −+
to be true.
Prove true for 1n k= +
i.e. 12!
23!
34!
...1 ! 1 1 !
111 1 !
kk
kk k( ) ( ) ( )+ + + +
++
+ += −
+ +
LHS 11
1 !12 !k
kk( ) ( )= −
++
++ (from assumption)
12 1
2 !
11
2 !RHS
k kk
k
( ) ( )( )
( )
= −+ − +
+
= −+
=
Hence the result is proven by mathematical induction.
1
1
1
1
1
Sample
page
s
19ISBN 978 1 4886 2147 5 Simple familiar worked solutions and examination report Set 2
Examination report comments Worked solutions Marks
% A % B % C % D % E % No Answer
6 24 6 62 2 0
The correct option is D.
Notes and pointers
4 Integrate acceleration to get the velocity equation.
∫∫ ( )
( ) ( )
( ) ( )( ) ( )
=
= + −
= + + +
-4 sin 2 20cos 2 20
2cos 2 10sin 2 10
-2
-2
v
i j k
i j k c
t t dt
t t e dt
t t e
t
t
a
Solve v(0) = 0 to determine the value of the constant of integration.
( ) ( )+ + = + + += −
0 0 0 2cos 2 10 sin 2 10-2 10
-2i j k i j k cc i k
t t e t
( )( ) ( )( ) ( )∴ = − + + −2cos 2 2 10sin 2 10 10-2v i j kt t t e t
% A % B % C % D % E % No Answer
5 4 14 7 68 1
The correct option is E.
( ) =E X 20, ( ) = =sd X2
25
2
5
Notes and pointers
5 This probability is calculated using a cumulative density function together with lower boundary of 19.3, upper boundary of ∞ , standard deviation and mean.
20E X( ) =
σ( ) =
=
=
=
225
250.4
sd Xn
19.3 0.9599P X( )> =
Marks 0 1 2 Average
% 3 17 80 1.8
Overall, most students answered this question well,
but incorrect arguments such as π3
or π6
were
common. The argument π5
3 was also accepted.
1 mark for the correct modulus
1 mark for the correct argument written in polar form
Notes and pointers
6 (a) (i) Sketching the point z1 on an Argand diagram will help ensure your answer is reasonable, particularly the angle as it is located in the fourth quadrant.
z ( ) ( )= +
==
3 -3
122 3
12 2
z
π
( ) =
=
=
Arg tan-3
3
- tan33
-3
1-1
-1
π∴ =
2 3 cis -
31z
1
1
1
1
Sample
page
s
20 Pearson Specialist Mathematics 12 Exam Preparation Workbook Queensland ISBN 978 1 4886 2147 5
Examination report comments Worked solutions Marks
Marks 0 1 Average
% 33 67 0.7
This question was answered reasonably well, but
many students did not express their angle in the
interval π π ](- , . A number of students gave the entire
expression for ( )z14 as an answer.
Notes and pointers
(ii) Recall that r r nn nθ = θ( cis ( )) cis( ). When working with angles, ensure your answer is a principle argument.
π
π
π
( ) ( )= ×
= ×
=
=
Arg 4 Arg
4 -3
-43
23
14
1z z
Marks 0 1 2 Average
% 14 20 66 1.6
This question was answered reasonably well. Most
students could find the conjugate root, but a number
could not obtain -2 3, often omitting the negative
sign. A number of students gave factors instead of
the roots.
1 mark for first root correct
1 mark for second root correct
Notes and pointers
(iii) There are three roots because the polynomial is cubic. The roots all have the same modulus and are equidistant from each other in angle.
Therefore these roots are π23
apart.
π π
π
= +
=
= +
2 3cis -3
23
2 3cis3
3 3
2z
i
π π
π( )
= +
==
2 3cis3
23
2 3cis-2 3
3z
% A % B % C % D % E % No Answer
6 65 14 11 4 0
The correct option is B.
Notes and pointers
7 Locate the given point (0, -1) on the gradient field and trace either direction using the gradient field. Check each option to see which best fits on the drawn line.
40-1-2-3-4 1 2 3
3
1
2
-1
-2
-3
y
x
(3.5, -2.5)
(0, -1)
A solution that includes (0, -1) also includes (3.5, -2.5).
1
1
1
1
Sample
page
s
21ISBN 978 1 4886 2147 5 Simple familiar worked solutions and examination report Set 2
Examination report comments Worked solutions Marks
Note: This question is from a Northern Hemisphere
examination paper. Examiner reports do not supply a
breakdown of marks achieved by the student cohort for
these papers.
The correct option is C.
Notes and pointers
8 The denominators for this partial fraction must be x, (x − 2) and (x − 2)2 because a linear term to a power must be shown, with each power starting at 1 until the power indicated, in this case 2.
This leaves only options C and E. Since the quadratic denominator is a perfect square, the numerator must be a constant. This means option C is the correct option. 1
Sample
page
s